Method for Reducing Body Diode Conduction in NMOS Synchronous Rectifiers

ABSTRACT

A switching regulator that practices the current invention includes a high-side switch M1 connected between an input voltage and a node L x . A low-side switch is connected between the node L x  and ground. An inductor L is connected between L x  and an output node (V OUT ). A filtering capacitor connects V OUT  to ground. The switching regulator has two distinct operational phases. During the first operational phase, the high-side switch is OFF and the low-side switch is ON. During the second operational phase, the high-side switch is ON and the low-side switch acts as a current source. During transitions between the second and first operational phases, the low-side switch is controlled to momentarily decrease the regulated drain-to-source current.

BACKGROUND OF THE INVENTION

Switching regulators are intended to be efficient machines for converting an input voltage to an output voltage. The two most common types of switching regulators are Boost (voltage increasing converters) and Buck (voltage decreasing regulators). Both Boost and Buck regulators are very important for battery powered applications such as cellphones. As shown in FIG. 1A, a traditional implementation for a Buck regulator includes a switch M1 connected between an input voltage (V_(BATT) in this case) and a node V_(x). A diode D is connected between the node V_(x) and ground. An inductor L is connected between V_(x) and the output node (V_(OUT)) of the regulator. A filtering capacitor connects V_(OUT) to ground. The node V_(OUT) is also connected to a load (not shown).

A control circuit turns switch M1 ON and OFF in a repeating pattern. This causes the Buck regulator to have two distinct operational phases. In the first phase, shown in FIG. 1 B, the switch M1 is ON. During this phase, called the charging phase, the inductor is connected between the battery and the output node V_(OUT). This causes current to flow from the battery to the load. In the process energy is stored in the inductor L in the form of a magnetic field.

In the second, or discharge phase the switch M1 is opened (see FIG. 1C). In this phase the diode and inductor are connected in series between ground and the load. In this phase, current supplied by the inductor's magnetic field flows to the output node V_(OUT) and the load. As the inductor's magnetic field collapses and the voltage over the inductor falls, the diode prevents current flowing through the inductor from reversing direction and flowing from the load to ground.

In general, switching regulators work in environments where both the input and output voltage are dynamic voltages. Input voltages change as battery voltages decline over time or as other components draw more power. Output voltages change depending on load requirements. Switching regulators react to changes in input and output voltages by varying the amount of time that the switch M1 remains ON. This is done using two different methods. In the first method, the switching frequency is varied—as the load on the regulator increases (relative to its supply) the switching frequency is increased. This is known as pulse frequency modulation or PFM. In the second method a fixed switching frequency is used and the amount of time that the switch M1 is turned ON is varied. For larger loads, the switches stay ON longer. This is known as pulse width modulation of PWM. Of the two methods, PWM is often preferred because it produces noise at a known and therefore filterable fixed frequency. Filtering the noise created by a PFM regulator can be problematic—especially in portable applications.

The regulator architecture just illustrated suffers one fundamental flaw: the diode D has, by nature a forward voltage drop. Depending on the type of diode, this can be fairly small, but is still generally unacceptable for low voltage applications. For this reason, it is common to replace the diode D with a second switch M2. FIG. 2A and 2B show Boost and Buck regulators of this type, respectively. The basic idea is that the switch M2 operates with no voltage drop (when switched ON) overcoming the disadvantages inherent in diode based designs.

In regulators of this type, the switch M1 is often referred to as the high-side switch and the switch M2 is referred to as the low-side switch. The switch M2 is also referred to as a “synchronous rectifier” because the two switches are driven synchronously—when one is ON, the other is OFF. In the real world, this is never quite the case. It takes time to turn the switches ON and OFF and control cannot be done with absolute precision. For this reason, the act of turning a switch OFF is always done slightly in advance of the act of turning the other switch ON. This technique, known as break-before-make or BBM avoids the situation where both switches are ON at the same time and power is connected to ground (a condition known as shoot through).

In many switching regulators, the high and low-side switches are fabricated as MOSFET devices that are integrated monolithically with the control circuit. During the time between switching OFF the low-side switch and the switching ON of the high-side switch, when the channels of both high and low side MOSFET devices are not conducting, the inductor current forward biases the body diode in the low side MOSFET switch. This is undesirable for the following reasons:

-   -   1) Minority carriers are injected into the substrate (on which         the MOFSET devices are fabricated) which may upset other         circuits controlling the power devices;     -   2) The forward biased body diode must be reversed before the         high side switch can fully conduct; and     -   3) The larger voltage drop across the body diode compared to the         voltage drop across the channel is less efficient.

SUMMARY OF THE INVENTION

An embodiment of the present invention includes a method for reducing body diode conduction in NMOS synchronous rectifiers. The method is intended to be used in all applications where synchronous rectifiers are used and is particularly applicable to synchronous DC/DC switching power converters. The invention is specifically intended to include physical implementations (apparatus) that correspond to the described method.

A typical Buck switching regulator that practices the current invention includes a high-side switch connected between an input voltage (V_(BATT) in this case) and a node L_(x). A low-side switch is connected between the node L_(x) and ground. An inductor L is connected between L_(x) and the output node (V_(OUT)) of the regulator. A filtering capacitor connects V_(OUT) to ground. The node V_(OUT) is also connected to power a load.

In gross terms, the high and low-side switches are switched out of phase-when one is ON, the other is OFF. This generalization ignores break-before-make periods where both switches are momentarily OFF to prevent shoot through. Also ignored in this generalization is the operation of the low-side switch which is never actually turned OFF. Instead, the low-side switch is either enhanced (i.e., ON) or is operated to provide a substantially constant drain-to-source current (i.e., operates as a current source).

Operation of the low-side switch in this manner gives the switching regulator two distinct operational phases. During the first operational phase, the high-side switch is OFF and the low-side switch is ON. During the second operational phase, the high-side switch is ON and the low-side switch acts as a current source.

Importantly, during transitions between the second and first operational phases, the low-side switch is controlled to momentarily decrease the regulated drain-to-source current. This prevents the high-side switch from conducting excess current as the high-side switch is turned OFF and the low-side switch is turned ON.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a block diagram of a prior art buck switching regulator.

FIG. 1B is a block diagram showing the prior art buck switching regulator of FIG. 1 during the charge phase of operation.

FIG. 1C is a block diagram showing the prior art buck switching regulator of FIG. 1 during the discharge phase of operation.

FIG. 2A is a block diagram of a prior art boost switching regulator that includes a low-side switch.

FIG. 2B is a block diagram of a prior art buck switching regulator that includes a low-side switch.

FIG. 3 is a block diagram of a buck switching regulator implemented to use the method for reducing body diode conduction provided by the present invention.

FIG. 4A is a block diagram of the buck switching regulator of FIG. 3 during rectifying mode operation.

FIG. 4B is a block diagram of the buck switching regulator of FIG. 3 during non-rectifying mode operation.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

An embodiment of the present invention includes a method for reducing body diode conduction in NMOS synchronous rectifiers. The method is intended to be used in all applications where synchronous rectifiers are used and is particularly applicable to synchronous DC/DC switching power converters. The invention being described is specifically intended to include physical implementations (apparatus) that correspond to the described method.

FIG. 3 shows a buck type switching regulator 300 implemented using the method for reducing body diode conduction. As shown in FIG. 3, buck regulator 300 includes a high-side PMOS device MP1 connected between an input voltage (V_(BATT) in this case) and a node L_(x). A low-side NMOS device MN1 is connected between the node L_(x) and ground. An inductor connects the node L_(x) to an output node V_(OUT) and a capacitor C1 connects the output node V_(OUT) to ground. A feedback voltage VFB is derived from the output node V_(OUT). VFB is typically proportional to the voltage at output node V_(OUT) and is typically derived using a resistor divider (not shown).

Low-side NMOS device MN1 is connected to be controlled by a low-side driver circuit 302. High-side PMOS device MP1 is similarly connected to be driven by a high-side driver circuit 304. The two driver circuits (302 and 304) are connected to be driven by a PWM/PFM controller in series with a break before make circuit. The PWM/PFM controller produces a pulse width modulation (PWM) or pulse frequency modulation (PFM) signal in response to the feedback voltage V_(FB). The PWM/PFM controller may use any form or combination of PWM or PFM methods. PWM/PFM controller may also be implemented to use light load power saving strategies including sleep mode, pulse skipping or burst mode.

The BBM circuit modifies the signal produced by the PWM/PFM controller to ensure that there are no cases where low-side NMOS device MN1 and high-side PMOS are simultaneously ON. In general, it should be appreciated that PWM/PFM controller and BBM circuit are intended to be representative of a wide range of circuits that may be used to produce control signals for the switches in switching regulators.

High-side driver circuit 304 includes a series of inverters. Each inverter is sized to amplify the signal produced by the BBM circuit.

Low-side driver circuit 302 includes a similar series of inverters. The output of the final inverter drives the gate of a PMOS device MP2 and the gate of an NMOS device MN3. MP2 and MN3 are cascode connected with the drain of MP2 connected to the drain of MN3 at a node DL. The node DL is connected to drive the low-side NMOS device MN1.

The source of MN3 is connected to the drain of another NMOS device MN2. The source of MN2 is connected to ground. The NMOS device MN2 is diode-connected through a transistor R1. A current source drives the gate of MN2 and supplies current through the transistor R1 and MN2 to ground. An AC circuit couples the gate of MN2 to the input of the high-side driver circuit 304.

The low-side driver circuit 302 operates in two different modes: a first mode in which the low-side NMOS device MN1 is ON and a second mode in which the low-side NMOS device MN1 acts as a current source. The first mode occurs when the input signal to the low-side driver circuit 302 is driven low. This causes the PMOS device MP2 to be fully enhanced and the NMOS device MN3 to be depleted. As shown in FIG. 4A, the resulting circuit couples the gate of low-side NMOS device MN1 to the supply voltage. This causes the low-side NMOS device MN1 to be fully enhanced allowing current to flow from ground through the inductor to the output capacitor and load.

The second mode occurs when the input signal to the low-side driver circuit 302 is driven high. This causes the PMOS device MP2 to be depleted and the NMOS device MN3 to be enhanced. As shown in FIG. 4B, the resulting circuit causes the NMOS device MN2 to be diode connected through R1. The gate bias voltage DL for MN1 is determined by the current Ibias, into the diode connected MN2. In this configuration, MN2 is configured to act as a MOS current mirror. The current mirror control voltage is presented at the gate of MN1 which makes MN1 a current source. The value of Ibias may be chosen to set the current in MN1. To reduce body diode conduction, ibias may be chosen so that the current in MN1 is on the order of micro amps (e.g., between 5 and 50 p amps.

The AC circuit that includes capacitor C2 is required to prevent MN1 from conducting too much during conduction transition between the power devices MN1 and MP1. As MP1 begins to conduct, LX rapidly transitions from a low to a high voltage. This transition generally couples the gate of MN1 high which can result in shoot through current directly from MP1 through MN1 to ground. To prevent this, a low impedance path is generally provided from the gate of MN1 to ground in order to keep MN1 OFF. However, in this invention, it is desirable to keep MN1 conducting as a current source. With the DL voltage near the threshold of MN1 in the DC operating point, this is a problem since a small amount of voltage coupling into DL can cause DL to exceed the threshold and induce conduction. To prevent this, C2 is used to couple the bias voltage high and the DL voltage low during the transition of MP1 conducting. After MP1 is conducting, the bias voltage returns to the level where MN1 can conduct a small amount of current. R1 serves to de-couple the gate of MN2 from DL when C2 is coupling the gate of MN2 to a high voltage level. When the voltage “bias-couple” from the high side drive has finished transitioning, and the current in C2 has diminished, R1 rapidly charges bias back to the proper operating point. It is desirable to couple the gate of MN2 high before the power device MP1 begins to conduct, so the coupling voltage is ideally taken from a signal that transitions prior to the gate of MP1 that is in phase with the LX voltage.

In discontinuous conduction, since the high side is not transitioned, a soft transition is achieved from a high voltage on DL to the reference bias voltage level on DL. This allows the current in MN1 to decay through the channel of MN1 rather than through the body diode, and diminishes the L, C, R tank oscillation seen on the LX node.

In continuous conduction, a soft transition from an ON state to a state where MN1 acts as a current source means that the channel of MN1 conducts during the break before make period instead of the body diode. 

1. A method for operating a switching regulator, where the switching regulator includes a high-side switch and a low-side switch, the method comprising: controlling the low-side switch to be substantially enhanced during a first operational phase; controlling the low-side switch to provide a regulated drain-to-source current during a second operational phase; and controlling, during transitions between the second and first operational phases, the low-side switch to momentarily decrease the regulated drain-to-source current.
 2. A method as recited in claim 1 that further comprises: enabling a current mirror to generate the gate voltage for the low-side switch during the second operational phase.
 3. A method as recited in claim 2 that further comprises: using a current source to supply the gate and drain of a diode-connected N-channel MOSFET; and using the drain voltage of the N-channel MOSFET as the gate voltage of the low-side switch.
 4. A method as recited in claim 3 that further comprises: controlling the high-side switch to be substantially depleted during the first operational phase and to be substantially enhanced during the second operational phase.
 5. A method as recited in claim 4 that further comprises: providing an AC coupling between a voltage used to drive the high-side switch and the gate of the N-channel MOSFET to momentarily decrease the low-side drive voltage during transitions between the second and first states of circuit operation.
 6. A switching regulator that includes: a high-side switch; a low-side switch; a low-side driver circuit that controls the low-side switch to be substantially enhanced during a first operational phase and to provide a regulated drain-to-source current during a second operational phase; and a coupling circuit, that momentarily decreases the regulated drain-to-source current, during transitions between the second and first operational phases.
 7. A switching regulator as recited in claim 6 that further comprises: a current mirror that is enabled during the second operational phase to generate the gate voltage for the low-side switch.
 8. A switching regulator as recited in claim 7 in which the current mirror further comprises: a diode connected N-channel MOSFET having its drain connected to supply the gate voltage of the low-side switch; and a current source to supply the gate and drain of the diode-connected N-channel MOSFET.
 9. A switching regulator as recited in claim 8 that further comprises: a high-side driver circuit configured to control the high-side switch to be substantially depleted during the first operational phase and to be substantially enhanced during the second operational phase.
 10. A switching regulator as recited in claim 9 that further comprises a AC coupling circuit connected between a voltage used to drive the high-side switch and the gate of the N-channel MOSFET to momentarily decrease the low-side drive voltage during transitions between the second and first states of circuit operation. 